Restricted activation of general amino acid control under conditions of glutamine limitation in Neurospora crassa

Cpc1 mediates cross-pathway control independently of Mbf1 in Fusarium fujikuroi

The deletion of glnA, encoding the glutamine synthetase (GS), had led to the down-regulation of genes involved in secondary metabolism and up-regulation of cpc1, the cross-pathway control transcription factor. In the present study, a Deltacpc1 mutant was created and used for transcriptional profiling by macroarray analysis. Most of the Cpc1 target genes were amino acid biosynthesis genes besides a homologue of the multi-protein bridging factor MBF1 that binds to the yeast Cpc1 homologue GCN4. We show that Deltambf1 mutants exhibit no Cpc1-related phenotype and that both proteins do not interact with each other in Fusarium fujikuroi. Moreover, results presented here suggest that Cpc1 is not responsible for the GS-dependent down-regulation of secondary metabolism and that its role is focused on the activation of amino acid biosynthesis in response to the amino acid status of the cell. Surprisingly, cross-pathway control is repressed by nitrogen limitation in an AreA-dependent manner.

cpc-3, the Neurospora crassa homologue of yeast GCN2, encodes a polypeptide with juxtaposed eIF2alpha kinase and histidyl-tRNA synthetase-related domains required for general amino acid control

Based on characteristic amino acid sequences of kinases that phosphorylate the alpha subunit of eukaryotic translation initiation factor 2 (eIF2alpha kinases), degenerate oligonucleotide primers were constructed and used to polymerase chain reaction-amplify from genomic DNA of Neurospora crassa a sequence encoding part of a putative protein kinase. With this sequence an open reading frame was identified encoding a predicted polypeptide with juxtaposed eIF2alpha kinase and histidyl-tRNA synthetase-related domains. The 1646 amino acid sequence of this gene, called cpc-3, showed 35% positional identity over almost the entire sequence with GCN2 of yeast, which stimulates translation of the transcriptional activator of amino acid biosynthetic genes encoded by GCN4. Strains disrupted for cpc-3 were unable to induce increased transcription and derepression of amino acid biosynthetic enzymes in amino acid-deprived cells. The cpc-3 mutation did not affect the ability to up-regulate mRNA levels of cpc-1, encoding the GCN4 homologue and transcriptional activator of amino acid biosynthetic genes in N. crassa, but the mutation abolished the dramatic increase of CPC1 protein level in response to amino acid deprivation. These findings suggest that cpc-3 is the functional homologue of GCN2, being required for increased translation of cpc-1 mRNA in amino acid-starved cells.

The cpc-2 gene of Neurospora crassa encodes a protein entirely composed of WD-repeat segments that is involved in general amino acid control and female fertility

Phenotypic and molecular studies of the mutation U142 indicate that the cpc-2+ gene is required to activate general amino acid control under conditions of amino acid limitation in the vegetative growth phase, and for formation of protoperithecia in preparation for the sexual phase of the life cycle of Neurospora crassa. The cpc-2 gene was cloned by complementation of the cpc-2 mutation in a his-2ts bradytrophic background. Genomic and cDNA sequence analysis indicated a 1636 bp long open reading frame interrupted by four introns. The deduced 316 amino acid polypeptide reveals 70% positional identity over its full length with G-protein beta-subunit-related polypeptides found in humans, rat (RACK1), chicken, tobacco and Chlamydomonas. With the exception of RACK1 the function of these proteins is obscure. All are entirely made up of seven WD-repeats. Expression studies of cpc-2 revealed one abundant transcript in the wild type; in the mutant its level is drastically reduced. In mutant cells transformed with the complementing sequence, the transcript level, enzyme regulation and female fertility are restored. In the wild type the cpc-2 transcript is down-regulated under conditions of amino acid limitation. With cpc-2 a new element involved in general amino acid control has been identified, indicating a function for a WD-repeat protein that belongs to a class that is conserved throughout the evolution of eukaryotes.